A power module includes a reactor vessel containing a coolant and a reactor core located near a bottom end of the reactor vessel. A riser section is located above the reactor core, wherein the coolant circulates past the reactor core and up through the riser section. In one embodiment, a coolant deflector shield includes flow-optimized surfaces, wherein the flow-optimized surfaces direct the coolant towards the bottom end of the reactor vessel. In another embodiment, the reactor housing includes an inward facing portion that varies a flow pressure of the coolant and promotes a circulation of the coolant past a baffle assembly and towards the bottom end of the reactor vessel.
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15. An upper portion of a nuclear reactor module, comprising:
a pressurizer region; and
a baffle assembly below the pressurizer region, the baffle assembly comprising:
an upper baffle plate proximate with the lower portion of the pressurizer region; and
a lower baffle plate below the upper baffle plate, wherein the lower baffle plate comprises a surface that curves downward toward a peripheral region of the lower baffle plate.
9. A baffle assembly for use in a nuclear reactor module, comprising:
an upper baffle plate exposed to a pressurized volume of saturated coolant; and
a lower baffle plate exposed to subcooled coolant, the subcooled coolant in fluid communication between a location proximate to a portion of the lower baffle plate and a location proximate with the upper baffle plate, wherein one or more of the upper baffle plate and the lower baffle plate are heated by the saturated coolant.
1. A nuclear reactor module, comprising:
a reactor vessel;
a pressurizer located at an upper portion of the reactor vessel;
a reactor core located at a lower portion of the reactor vessel;
a baffle assembly located between the reactor core and the pressurizer; and
a reactor housing having an inward-facing portion and a flow path through the reactor housing that fluidly couples the reactor core to a lower portion of the baffle assembly, the inward-facing portion comprising a curvature for reducing turning loss of a coolant flowing past the inward-facing portion, the inward-facing portion of the reactor housing comprising multiple wing-shaped extensions located about a perimeter of an upper portion of the reactor housing.
2. The nuclear reactor module of
3. The nuclear reactor module of
4. The nuclear reactor module of
5. The nuclear reactor module according to
6. The nuclear reactor module according to
7. The nuclear reactor module according to
8. The nuclear reactor module according to
10. The baffle assembly of
11. The baffle assembly of
12. The baffle assembly of
13. The baffle assembly of
14. The baffle assembly of
16. The upper portion of the nuclear reactor module of
17. The upper portion of the nuclear reactor module of
18. The upper portion of the nuclear reactor module of
19. The upper portion of the nuclear reactor module of
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This application is a divisional application of and claims priority to U.S. application Ser. No. 12/393,577, filed on Feb. 26, 2009, which claims priority to U.S. Provisional Patent Application Ser. No. 61/115,614, filed on Nov. 18, 2008. The entire contents of both applications are hereby incorporated by reference in its entirety.
The invention relates to the field of nuclear power generation, including systems designed to cool a reactor core.
In nuclear reactors designed with passive operating systems, the laws of physics are employed to ensure that safe operation of the nuclear reactor is maintained during normal operation or even in an emergency condition without operator intervention or supervision, at least for some predefined period of time. A nuclear reactor 5 includes a reactor core 6 surrounded by a reactor vessel 2. Water 10 in the reactor vessel 2 surrounds the reactor core 6. The reactor core 6 is further located in a shroud 122 which surrounds the reactor core 6 about its sides. When the water 10 is heated by the reactor core 6 as a result of fission events, the water 10 is directed from the shroud 122 and out of a riser 124. This results in further water 10 being drawn into and heated by the reactor core 6 which draws yet more water 10 into the shroud 122. The water 10 that emerges from the riser 124 is cooled down and directed towards the annulus 123 and then returns to the bottom of the reactor vessel 2 through natural circulation. Pressurized steam 11 is produced in the reactor vessel 2 as the water 10 is heated.
A heat exchanger 135 circulates feedwater and steam in a secondary cooling system 130 in order to generate electricity with a turbine 132 and generator 134. The feedwater passes through the heat exchanger 135 and becomes super heated steam. The secondary cooling system 130 includes a condenser 136 and feedwater pump 138. The steam and feedwater in the secondary cooling system 130 are isolated from the water 10 in the reactor vessel 2, such that they are not allowed to mix or come into direct contact with each other.
The reactor vessel 2 is surrounded by a containment vessel 4. The containment vessel 4 is designed so that water or steam from the reactor vessel 2 is not allowed to escape into the surrounding environment. A steam valve 8 is provided to vent steam 11 from the reactor vessel 2 into an upper half 14 of the containment vessel 4. A submerged blowdown valve 18 is provided to release the water 10 into suppression pool 12 containing sub-cooled water.
Water 10 circulates through the reactor vessel 2 as a result of temperature and pressure differentials that develop as a result of heat generation through reactor operation and through heat exchange with the secondary cooling system 130. Accordingly, the efficiency of the circulation depends on the thermal properties of the reactor module 5 as well as its physical design and geometry. Conventional nuclear reactors include certain design features that tend to provide less than optimal coolant circulation, and must therefore rely on increased coolant volume or redundant components to ensure sufficient performance.
The present invention addresses these and other problems.
A power module is herein disclosed as comprising a reactor vessel containing a coolant, and a reactor core located near a bottom end of the reactor vessel. A riser section is located above the reactor core, wherein the coolant circulates past the reactor core and up through the riser section. The power module further comprises a coolant deflector shield including an ellipsoidal or other flow-optimized surface, wherein the flow-optimized surface directs the coolant towards the bottom end of the reactor vessel.
A nuclear reactor module is herein disclosed as comprising a reactor vessel including an upper end and a lower end, a pressurizer located near the upper end of the reactor vessel, and a reactor core located near the bottom end of the reactor vessel. The nuclear reactor module further comprises a baffle assembly located between the reactor core and the pressurizer, and a reactor housing the directs coolant flow through the reactor core. The reactor housing comprises an inward facing portion that varies a flow pressure of the coolant and promotes a circulation of the coolant past the baffle assembly and towards the bottom end of the reactor vessel.
A method of cooling a reactor core is herein disclosed as comprising circulating a primary coolant through a reactor housing comprising an upper riser, and directing a flow of the coolant down a reactor vessel and around the reactor housing, wherein an ellipsoidal shaped lower end of the reactor vessel promotes coolant flow through the reactor core. An ellipsoidal or flow-optimized surface shaped deflector shield located above the upper riser promotes coolant flow around the reactor housing.
The invention will become more readily apparent from the following detailed description of a preferred embodiment of the invention which proceeds with reference to the accompanying drawings.
Various embodiments disclosed or referred to herein may be operated consistent, or in conjunction, with features found in co-pending U.S. application Ser. No. 11/941,024 which is herein incorporated by reference in its entirety.
In one embodiment, the containment vessel 54 is suspended in the pool of water 16 by one or more mounting connections 180. A reactor vessel 52 is located or mounted inside the containment vessel 54. An inner surface of the reactor vessel 52 may be exposed to a wet environment including a coolant 100 or liquid, such as water, and an outer surface may be exposed to a dry environment such as air. The reactor vessel 52 may be made of stainless steel or carbon steel, may include cladding, and may be supported within the containment vessel 54.
The power module assembly 25 may be sized so that it can be transported on a rail car. For example, the containment vessel 54 may be constructed to be approximately 4.3 meters in diameter and approximately 17.7 meters in height (length). Refueling of the reactor core 6 may be performed by transporting the entire power module assembly 50 by rail car or overseas, for example, and replacing it with a new or refurbished power module assembly which has a fresh supply of fuel rods.
The containment vessel 54 encapsulates and, in some conditions, cools the reactor core 6. It is relatively small, has a high strength and may be capable of withstanding six or seven times the pressure of conventional containment designs in part due to its smaller overall dimensions. Given a break in the primary cooling system of the power module assembly 25 no fission products are released into the environment. Decay heat may be removed from the power module assembly 25 under emergency conditions.
The reactor core 6 is illustrated as being submerged or immersed in a primary coolant 100, such as water. The reactor vessel 52 houses the coolant 100 and the reactor core 6. A reactor housing 20 comprises a shroud 22 in a lower portion and a riser 24 in an upper portion of the reactor housing 20. The riser 24 may be substantially cylindrical in shape. The shroud 22 surrounds the reactor core 6 about its sides and serves to direct the coolant 100 (shown as coolant flow 26, 28) up through the center of the riser 24 located in the upper half of the reactor vessel 52, then back down the annulus 23, as a result of natural circulation of the coolant 100. In one embodiment, the reactor vessel 52 is approximately 2.7 meters in diameter and includes an overall height (length) of approximately 13.7 meters. The reactor vessel 52 may include a predominately cylindrical shape with ellipsoidal, domed, concave, or hemispherical upper and lower ends. The reactor vessel 52 is normally at operating pressure and temperature. The containment vessel 54 is internally dry and may operate at atmospheric pressure with wall temperatures at or near the temperature of the pool of water 16.
The containment vessel 54 substantially surrounds the reactor vessel 52 and may provide a dry, voided, or gaseous environment identified as containment region 44. Containment region 44 may comprise an amount of air or other fill gas such as Argonne. The containment vessel 54 includes an inner surface or inner wall which is adjacent to the containment region 44. The containment region 44 may include a gas or gases instead of or in addition to air. In one embodiment, the containment region 44 is maintained at or below atmospheric pressure, for example as a partial vacuum. Gas or gasses in the containment vessel may be removed such that the reactor vessel 52 is located in a complete or partial vacuum in the containment region 44.
During normal operation, thermal energy from the fission events in the reactor core 6 causes the coolant 100 to heat. As the coolant 100 heats up, it becomes less dense and tends to rise up through the riser 24. As the coolant 100 temperature reduces, it becomes relatively denser than the heated coolant and is circulated around the outside of the annulus 23, down to the bottom of the reactor vessel 52 and up through the shroud 22 to once again be heated by the reactor core 6. This natural circulation causes the coolant 100 (shown as coolant flow 26, 28) to cycle through the heat exchanger 135, transferring heat to a secondary coolant, such as the secondary cooling system 130 of
The reactor vessel deflector shield 35 comprises a flow-optimized ellipsoidal, domed, concave, or hemispherical shaped portion 35A, wherein the flow-optimized portion 35A directs the coolant (shown as coolant flow 26) towards the bottom end 55 of the reactor vessel 52. The ellipsoidal portion 35A may come into direct contact with and deflect the coolant that exits the riser section 24. The ellipsoidal portion 35A operates to reduce a flow resistance or turning loss of the coolant flow 26, as compared to an interaction of the coolant with a flat, or irregular surface, or plenum region without a solid interface. In one embodiment, the reduction in turning loss is by a factor of four or five compared to systems without a deflector shield. The reactor vessel deflector shield 35 may be made of stainless steel or other materials which may be formed into an ellipsoidal or optimized shaped surface.
In one embodiment, the bottom end 55 of the reactor vessel 52 comprises a second flow-optimized ellipsoidal, domed, concave, or hemispherical portion 55A, wherein the second ellipsoidal portion 55A directs the coolant (shown as coolant flow 28) towards the reactor core 6. The ellipsoidal portion 35A and second ellipsoidal portion 55A increase flow rate and promote natural circulation of the coolant through the reactor core 6.
An optimization of the coolant flow 26 may be obtained according to a ratio of the distance Ho between the top of the riser section 24 and the center of the reactor vessel deflector shield 35 and the relative distance Do between the walls of the riser section 24, wherein the dimension La represents the distance between the outside of the riser 24 and the inside surface of the reactor vessel 52. In one embodiment, the distance Do equals the diameter of the riser section 24. The flow area inside the riser is Ao, the flow area inside the annulus is Aa. The optimized coolant flow ratios may be represented as Ho/Do and Aa/Ao. In one embodiment, the optimized coolant flow ratio Ho/Do comprises a value 0.1 and 2.0, and the flow ration and Ao/Aa comprises a value between/approximately 1 and 10. Further optimization of the coolant flow 26 may be obtained by modifying the radius of curvature of the surface of ellipsoidal portion 35A to eliminate/minimize boundary layer separation and stagnation regions.
The reactor vessel deflector shield 35 is illustrated as being located between the top of the riser section 24 and a pressurizer region 15. The pressurizer region 15 is shown as comprising one or more heaters 17 and a spray nozzle 19 configured to control a pressure, or maintain a steam dome, within an upper end 56 of the reactor vessel 52. Coolant located below the reactor vessel deflector shield 35 may comprise relatively sub-cooled coolant TSUB, whereas coolant in the pressurizer region 15 in the upper end 56 of the reactor vessel 52 may comprise substantially saturated coolant TSAT. A fluid level of the coolant is shown as being above the reactor vessel deflector shield 35, and within the pressurizer region 15, such that the entire volume between the reactor vessel deflector shield 35 and the bottom 55 of the reactor vessel 52 is full of coolant during normal operation of the power module assembly 30.
In one embodiment, the cross section of the inward facing portion 65 approximates a cross section of an airplane wing in shape, but with a smaller cross sectional area, for example. The cross-section blunt end of the inward facing portion 65 may face the top of the vessel or the bottom, or be blunt on both ends. The inward facing portion 65 may be continuously located around a perimeter of an upper end of the reactor housing 20 or riser section 24 (e.g.
The baffle assembly 50 comprises an upper baffle plate 62 and a lower baffle plate 64. A hot/cold liquid interface Lo due to stratification in the baffle region may exist between the upper and lower baffle plates 62, 64 separating the subcooled coolant TSUB from the saturated coolant TSAT. The liquid interface Lo provides a medium in which the first fluid entering the pressurizer region when flow is into the pressurizer, is hot fluid, and afterwards the subcooled coolant TSUB entering the pressurizer heats up (or mixes together with saturated coolant TSAT) before entering the pressurizer region 15. The baffle assembly 50 operates to impede a flow of the subcooled coolant TSUB from entering the pressurizer region 15, comprising substantially saturated coolant TSAT. The baffle assembly 50 helps maintain or create a thermal trap between the upper and lower baffle plates 62, 64. A steam dome may be maintained in pressurizer region 15, or the upper end 56 of the reactor vessel 52. If the subcooled coolant TSUB is allowed to enter the pressurizer region 15 too quickly, it may result in a loss of reactor vessel pressure or collapse of the steam dome.
The baffle assembly 50 effectively increases a flow path length from the subcooled coolant TSUB on a first side of the baffle assembly 50 to the saturated coolant TSAT on a second side of the baffle assembly 50. Coolant flow (illustrated as F1) entering the baffle assembly 50 is allowed to flow around or by the lower baffle plate 64. The coolant flow (illustrated as Fo) next maneuvers around one or more internal baffles 72, 74 before exiting into the pressurizer region 15 as coolant flow F2, through or by the upper baffle plate 62. The flow path made by the baffles directs the flow F1 past the structure of the baffle assembly 50 that is heated from the pressurizer region 15. Directing of the flow F1 past the relatively hot structure heats this fluid, and additionally mixes the fluid with the Tsat region, effectively heating it previous to it entering the pressurizer region 15.
The pressurizer region 15 is located at the upper end of the reactor vessel 52. The baffle assembly 60 is located between the pressurizer region 15 and the riser section 24. The baffle assembly 60 comprises one or more baffles 72, 76 located between an upper baffle plate 62 and the reactor vessel deflector shield 66. The one or more baffles 72, 76 impede a flow of the sub-cooled coolant TSUB into the pressurizer region 15. The baffle assembly 60 may be understood to operate similarly as a pressurizer surge line of a typical pressurized water reactor design. The baffle assembly 60 may prevent an insurge of coolant from the reactor vessel 52 from entering the pressurizer region 15 too suddenly or at too low of a temperature. In one embodiment, the baffle assembly 60 operates to control a rate of insurge of the coolant into the pressurizer region 15, and increases the temperature of the insurge flow by structure heat addition and mixing with hot fluids.
The baffle assembly 60 includes an upper portion which comprises the upper baffle plate 62. The upper baffle plate 62 may include, or be attached to, one or more baffles 72. The baffle assembly 60 further includes a lower portion which comprises the reactor vessel deflector shield 66. The reactor vessel deflector shield 66 may include, or be attached to, one or more baffles 76.
The baffle assembly 60 may comprise one or more heaters 79. The one or more heaters 79 may be provided intermediate the upper and lower baffle plates 62, 66. In one embodiment, the one or more heaters 79 are provided within the upper baffle plate 62 to warm the coolant. In another embodiment the one or more heaters 79 are provided in the liquid interface Lo. Coolant that passes through the baffle assembly 70 may become heated to at, or near, saturation temperatures TSAT while being transferred into the pressurizer region 15. The baffle assembly 60 may be understood to both isolate the pressurizer region 15 from the subcooled coolant TSUB, as well as promote increased flow rate of the coolant (illustrated as flow 26) in the reactor vessel 52.
In one embodiment, a width or diameter of the reactor vessel deflector shield 66 is less than a width or diameter of the reactor vessel 52 forming a pathway or channel 68 about the perimeter of the reactor vessel deflector shield 66. The channel 68 provides a path for the coolant flow (illustrated as F1) to pass by or through the reactor vessel deflector shield 66. Coolant continues to flow (illustrated as Fo) around the one or more baffles 72, 76 before exiting by or through the upper baffle plate 62 as coolant flow F2. Coolant that passes through the baffle assembly 60 may become heated to at, or near, saturation temperatures TSAT while being transferred through the pathway or channel 68 and being heated by the upper baffles 72.
Divider 77B further facilitates coolant 26 to flow in an outward direction from the center of the baffle plate 77. Divider 77B may be shaped similar to a bullet tip. Baffle plate 77 minimizes pressure loss of coolant flow based on an optimized position and geometry above the exit of the riser section 24.
The baffle assembly 70 is located between the pressurizer region 15 and the riser section 24. The baffle assembly 70 comprises one or more baffles 72, 78 located between the upper baffle plate 62 and the lower baffle plate 77. The one or more baffles 72, 78 impede a flow of the sub-cooled coolant TSUB into the pressurizer region 15.
An upper portion of the baffle assembly 70 comprises the upper baffle plate 62. The upper baffle plate 62 may include, or be attached to, one or more baffles 72. A lower portion of the baffle assembly 70 comprises the lower baffle plate 77. The lower baffle plate 77 may include, or be attached to, one or more baffles 78. A pathway or channel may be formed through one or all of the baffles 72, 78. The channel provides a path for the coolant flow (illustrated as F1) to pass by or through the lower baffle plate 77. Coolant continues to flow (illustrated as Fo) through the one or more baffles 72, 78 before exiting by or through the upper baffle plate 62 as coolant flow F2.
The baffle assembly 70 may comprise one or more heaters 79. The one or more heaters 79 may be provided intermediate the upper and lower baffle plates 62, 77. In one embodiment, the one or more heaters 79 are provided within the upper baffle plate 62 to warm the coolant entering the pressurizer region during an insurge. In another embodiment the one or more heaters 79 are provided in the temperature variation layer proximate to the liquid interface Lo. Coolant that passes through the baffle assembly 70 may become heated to at, or near, saturation temperatures TSAT while being transferred into the pressurizer region 15. The baffle assembly 70 may be understood to both isolate the pressurizer region 15 from the subcooled coolant TSUB, as well promote increased flow rate of the coolant (illustrated as flow 26) in the reactor vessel 52.
In one embodiment, the inward facing portion 65 has a cross section which approximates an inverted teardrop. The inward facing portion 65 has a cross section which generally increases in thickness towards an upper end of the riser region 24. The upper end of the reactor housing 20, or riser section 24, comprises a perimeter characterized by a rounded rim of the inverted teardrop.
At operation 210, a primary coolant is circulated through a reactor housing comprising an upper riser.
At operation 220, a fluid pressure of the coolant in the reactor housing is varied by directing a coolant flow around an inward facing portion of the upper riser.
At operation 230, a flow-optimized ellipsoidal, domed, concave or hemispherical shaped deflector shield forms a lower portion of a baffle system that inhibits the flow of coolant into a pressurizer region. In one embodiment, the flow-optimized ellipsoidal deflector shield is located between the upper riser and the pressurizer region, wherein the pressurizer region is located in an upper end of reactor vessel.
At operation 240, a flow of the coolant is directed down the reactor vessel and around the reactor housing. A flow-optimized ellipsoidal, domed, concave or hemispherical shaped lower end of the reactor vessel promotes coolant flow through the reactor core, and the flow-optimized ellipsoidal deflector shield located above the upper riser promotes coolant flow around the reactor housing.
Although the embodiments provided herein have primarily described a pressurized water reactor, it should be apparent to one skilled in the art that the embodiments may be applied to other types of nuclear power systems as described or with some obvious modification. For example, the embodiments or variations thereof may also be made operable with a boiling water reactor.
The rate of fluid flow about the reactor housing, the rate of insurge and outsurge flows within the baffle assemblies, and the variation in pressure of the fluid moving about flow augmentation devices, as well as other rates and values described herein are provided by way of example only. Other rates and values may be determined through experimentation such as by construction of full scale or scaled models of a nuclear reactor fluid system.
Having described and illustrated the principles of the invention in a preferred embodiment thereof, it should be apparent that the invention may be modified in arrangement and detail without departing from such principles. We claim all modifications and variation coming within the spirit and scope of the following claims.
Young, Eric Paul, Reyes, Jr., Jose N., Groome, John T.
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Feb 06 2009 | REYES, JOSE N | NUSCALE POWER | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 028855 | /0164 | |
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